FR2586096A1 - DEVICE FOR STARTING AN EXPLOSIVE LOAD - Google Patents

Abstract

EXPLOSIVE CHARGE INCLUDING COATING 3 FORMING DART OR ARMATURE FORMING DART OR PROJECTILE FORMING, AN INITIAL ROCKET 11, AN INITIAL CHARGE AND A MAIN CHARGE 4. THE EXPLOSIVE CHARGE INCLUDES A SEAL OF INERT MATERIAL (DIVISIONS 6 TO 10) THE INITIAL LOAD IN SEVERAL ZONES 19-23 CONCENTRIC TO THE DRIVE AXLE 5 AND DISTANCE FROM ONE OF THE OTHERS FOR THE INTRODUCTION OF THE DETONATION WAVE IN THE MAIN LOAD 4. THE LENGTH OF THE WAVE PATHS DETONATION STARTING FROM PRIMING ROCKET 11 PASSING THROUGH THE VARIOUS ZONES 19 TO 23 AND ENDING COATING 3 OR THE FRAME CAN BE ADJUSTED, WHEREAS THE POSSIBILITY OF MODIFYING THE SHOCK WAVE AT ITS IMPACT ON THE COATING 3.

Description

"Priming device for an explosive charge"

  The invention relates to a device for

  an explosive charge, with a strong coating

  mant dard or a frame forming a dart or forming a projectile,

  the priming being carried out from a rocket and propagating

  an initial charge before reaching the main charge surrounding the coating or armature, the detonation wave being transmitted to the main charge by means of a liner of inert material placed in front of it in such a way that that the front of the detonation wave to its

  impact on the entire coating or reinforcement

feels a determined pace.

  The speed gradient in the sting and consequently

  The shape of the latter is determined by the appearance of the front of the detonation wave at its impact on the coating or lining. So, in case of a parallel provision

  from the front of the detonation wave to its impact on the

  or reinforcement, a dart is formed without a speed gradient, ie a relatively short dart which remains

  very effective even at great distances.

  Moreover, a non-parallel arrangement, therefore a grazing impact of the front of the detonation wave arriving at a given angle on the coating or reinforcement

  produces a certain degree of velocity in the dart, that is,

  to form a dart that lengthens rapidly away from the point of depression. Such a relatively long and thin dart causes, admittedly, a hole also thin during the perforation of a shield, but has a depth of

penetration all the greater.

  In order to obtain, at least in zones, a parallel arrangement of the front of the detonation wave at the moment of its impact on the coating or the reinforcement, the explosive charges of this type are currently provided with an inert material lining which is arranged between the bottom firing rocket and the liner and directs the detonation wave

  accordingly on the coating or the frame.

  A device of the aforementioned type is already known which transmits the wave of the detonation to the main charge so that the front of the detonation wave during the impact on the entire coating or reinforcement is

  arranged parallel to the latter (German patent.

  28 07 258). In such a case, the packing made of inert material constitutes a continuous barrier between the initial charge and the main charge, so that a delay transmission of the detonation wave is controlled between the initial charge and the main charge. by an appropriate configuration of the wall thickness of the barrier, the passing detonation wave

  the barrier penetrates simultaneously into the main charge.

  In the known device, the difficulty consists

  however, to mutually agree on the dimensions and the

  the initial charge, barrier and main charge to obtain the desired front of the detonation wave. Another difficulty is to obtain an intensity of the detonation wave coming out of the barrier

  which is sufficient for the priming of the main charge.

  Moreover, the known device requires a relative report

  between the length of the explosive charge and

its diameter.

  With a device of the aforementioned type, the invention

  therefore to develop an explo-

  sive with which the detonation wave can be easily transmitted to the main charge and which confers on the

  the detonation wave a determined disposition, in parti-

  parallel during its impact on the entire cladding or reinforcement. The device according to the invention makes it possible to easily establish or eliminate a speed gradient in the stinger. As variables for adjusting the speed gradient, it is possible to use, according to the invention, both the dimensions of the initial charge and those of the main charge. If, the paths of the detonation wave starting from

  the firing rocket, crossing the initial charge and reaching

  different areas of the introduction of the detonation wave to, from there, cross the main charge and

  the shortest way to the pavement or armament

  are also long for all introductory zones.

  In the detonation wave, a detonation wavefront is obtained, which arrives parallel to the coating or reinforcement and consequently causes a simultaneous depression of the coating or reinforcement, thus forming a dart without velocity gradient, assuming that the velocity of the detonation wave is the same in the initial charge and in

the main charge.

  An extension of the stinger away from the point of

  As a result, the sting remains effective even in fairly remote areas. Such a dart without a speed gradient is particularly important in the case of partition objectives or special objectives with components that destroy the darts. In the near zone in the affected armor, a hole-shaped channel of constant cross-section is obtained, so that after perforation of the armor the dart still retains a high efficiency.

residual.

  The possibility of adjusting the speed gradient of the stinger, the speed of deformation of a flat load or the formation of the projectile, provided by the device according to the invention, generally makes it possible to sufficiently optimize the explosive charges used against special objectives that can not be effectively combated by

conventional explosive charges.

  The end sections of the dart, which are formed by the tip or base of the liner or reinforcement and

  which have a relatively low speed, can be

  in the form of a coating or reinforcement in the form of a pot or truncated cone, that is by shortening it both at the base and at the tip relative to

  to a conventional tapered cladding or reinforcement.

  In this way, with the device according to the invention,

  For the same efficiency, it is possible to reduce the mass of the explosive as well as that of the coating with respect to conventional explosive charges, that is to say to increase

  considerably the yield, defined by the mass of the former

  plosive and the mass of the coating in relation to the material

highly effective sting.

  Moreover, with the device according to the invention, it is possible to realize an explosive charge which is relatively

  short and thus has a length / diameter relationship

  small, for example 2: 1, preferably 1: 1.

  Such a flat load is particularly suitable for transverse mounting in missiles (Overflying system

Top Attack ").

  The invention will be better understood with the aid of

  description of an embodiment taken as an example, but not limited to, and illustrated by the appended drawing of which

  figure represents schematically a longitudinal section

dinal of a hollow charge.

  In the drawing, the hollow charge comprises a case 1, a bottom 2 and a coating 3, for example made of copper, in the form of a pot or truncated cone. Inside the hollow charge is the main charge 4 which is in the form of a conical envelope adapted to the coating 3 around which it is arranged. Inside are also provided several sections 6 to 10 of inert material, for example plastic, such as polyvinyl chloride, which are installed concentrically to the driving axis 5 and arranged at a distance from each other. others in the sense of

the driving axis 5.

  The first section 6 made of inert material is

  between the priming rocket 11 of the bottom 2 and the coating

  3 and is made in the form of a disc. The other sections 7 to 10 are installed around the coating 3 and also made in the form of disks with, however, appropriate central recesses through which the load extends.

principal 4.

  An initial charge is provided for the initiation of

  the main charge. 4. It consists of a section of ex-

  tremité 12 which extends from the ignition rocket 11 to the case 1 between the bottom 2 and the first section 6 and a lateral section 13 which, starting at the end section 12, is arranged between the case 1 and the sections 6 to 10 of inert material, and the lateral section 13 start from the connecting branches 14 to 18 of the initial charge which open into the annular zones 19 to 23 for the transmission of the detonation wave to the main load 4. The connecting branches 14 to 17 are here respectively inserted between two sections 6 to 10 of inert material. The connection branch 18 adjacent to the base 3 "has a length zero in the embodiment

  represented by the device according to the invention.

  The length of the path of the detonation wave from the firing rocket 11 to the various zones 19 to 23 for introducing the detonation wave is constituted by the path starting from the firing rocket 11, passing through the end section 12 and terminating at the first branch 24 of the first connecting branch 14 between the first section 6 and the adjacent segment 7, as well as by the length a1 thereof with respect to the first branch of connection 14 and, in the case of the other

  connecting branches 15 to 18, by their respective lengths

  tives a2 to a5, on the one hand, and by the distance b1 to b4 separated

  the connections 25 to 28 of the corresponding connecting branches 15 to 18 of the first branch 24, on the other hand, the length of the connection branch 18 close to the base 3 "of the coating can also be equal to zero,

  as shown and shown in the drawing.

  Zones 19 - 23 for introducing the detonation wave start from partial detonation waves which, in the main charge 4, are superimposed on one front

  substantially linear detonation waveform in longitudinal section.

  tudinal which then arrives on the coating 3.

  Therefore, the distance of the zones 19 to 23 of introduction of the detonation wave relative to each other

  to others and the thickness of the layer of

  4 are mutually tuned so that the partial detonation waves entering the main charge 4 at these areas 19 to 23 are superimposed to form

  such a straight front of the detonation wave.

  In this way, the length of the detonation wave path from the firing rocket 11, passing through the various zones 19 to 23 and, from these zones 19 to 23, arriving by the shortest path at coating 3 through the main charge 4, can be adjusted so that the front of the detonation wave at the moment of its

  impact on the coating 3 has the desired pace.

  If a dart without a speed gradient is desired, it is necessary that the front of the detonation wave at its impact on the coating 3 is, if possible, arranged parallel thereto. To do this, the length of the different paths must be equal, therefore that of the first path which includes the length a1 of the connecting branch 14 and

  the distance c1 between the corresponding zone 19 of introduc-

  detonation wave and the coating 3, that of the second path which comprises the distance b1 of the second branch 25 with respect to the first branch 24, the length a2 of the second branch branch 15 and the distance c2 between the area corresponding 20 of introduction

  of the detonation wave and the coating 3, that of the third

  sth course which comprises the distance b2 of the third branch 26 with respect to the first branch 24, the length a3 of the third branch 16 and the distance c3 between the corresponding zone 21 of introduction

  of the detonation wave and the coating 3, that of the

  third course which comprises the distance b3 of the fourth branch 27 relative to the first branch 24, the length a4 of the fourth branch 17 and the distance c4 between the corresponding zone 22 for introducing the detonation wave and the coating 3 as well as that of the fifth course which, like the length aS of the branch

  18 is zero in this embodiment.

  tion, comprises only the distance b4 of the fifth branch 28 relative to the first branch 24 and the distance c5 between the corresponding zone 23 for introducing the detonation wave and the coating 3, and this, under

  provided that the initial load at least of the lateral section

  13 and connecting branches 14 to 18 and the main load 4 are constituted respectively by the same

  explosives or explosives with the same speed of

the detonation wave.

  This ensures that the travel time of the detonation wave from the firing rocket 11 and passing through the various zones 19 to 23 to the coating 3, is equal for all elements thereof

(an + bn + cn = constant).

  The thickness of the layer of the main charge 4 increases since the narrowed end 3 'of the coating 3

  up to its base 3 "(c1 <c5), and preferably

  to increase the diameter of the coating 3. This ensures that the same amounts of explosives are always

  which act behind the surface elements of the coating 3.

  In order to obtain an undisturbed propagation of the detonation wave in the initial charge, it must be that the latter, including the connecting branches 14 to 18, have a minimum determined thickness, preferably a minimum

minimum thickness of 1 mm.

  The different detonation waves which pass through the connecting branches 14 to 18 generate behind them a shock wave in the sections 7 to 10 made of inert material. In order for this shock wave to reach the adjacent connecting branch 14 to 18 only after the front of the detonation wave has passed through it, it is necessary that the

  sections 7 to 10 made of inert material have a minimum thickness

  determined male. In the case of sections 7 to 10 made of

  inert, this is at least 10 mm.

  To obtain an approximate detonation wavefront

  in rectilinear section in longitudinal and radially symmetrical section during its impact on the coating 3, it is necessary that the shortest path c1 to c5 between the annular zones

  19 to 23 of introduction of the detonation wave and the coating

  3 is a multiple, preferably at least three, of the thickness of the connection legs 14 to 18 at

level of said zones 19 to 23.

  In the case of a hollow charge, comprising the device according to the invention, the shortened configuration in the form of a truncated cone or

  coating pot 3, whereas in

  usual, the tip as well as the area of the base forms

  dart sections of relatively low speed.

Claims (10)

  1. Device for priming an explosive charge, comprising a dart coating or an armature forming   dart or projectile, the priming being carried out   firing a rocket and propagating through an initial charge before reaching the main charge surrounding the liner or armature, the detonation wave being transmitted to the main charge by means of a lining of a material inert placed in front of it so that the front of   the detonation wave at its impact on the entire   ment or frame has a certain speed, which is   characterized by the fact that the lining of inert material divides   the moment of detonation when it passes the initial charge   tia] e (12-18) at the main loadfflen several areas (19-23) concentric to the driving axis (5) and arranged at axial distance from each other, and that -the length of the courses of the detonation wave from the firing rocket (11) passing through the different zones (19-23) for introducing the detonation wave and resulting in the coating (3) or the armature can be adjusted in accordance with the desired pace of the front of the detonation wave at the moment of its impact on the coating (3) or the armature 2. Device according to claim 1, characterized by the fact that the packing of inert material is composed   several sections (6-10) concentric with the axis of   5 and arranged at an axial distance from each other, a first section (6) being placed between the ignition rocket   (11) and the coating (3) or reinforcement, and the other sections   (7-10) around the main load and the coating (3) or the frame so as to form between the bottom (2) o of the expjosive load and the first section (6), an end section (12) of the initial charge and between the case (]) of the explosive charge and the sections (6-10), a lateral section of the initial charge, connecting branches (14-18), separated from each other other by the sections (7-10) made of inert material, from the initial charge, starting from the lateral section (13) and resulting in   annular zones (19-23) for introducing the detonation wave nation.   3. Device according to claim 2, characterized   characterized in that in case of parallel disposition of the front of the detonation wave to its impact on the coating (3) or the armature and equally high speed thereof in the initial charge (12-18) and in the main charge (4), the length of the detonation wave path from the firing rocket (11) through the different zones (19-23) and from there to the shortest path to the liner (3) or frame, is equal for all areas   (19-23) introduction of the detonation wave.   4. Device according to any one of the claims   tions, characterized by the fact that the thickness   of the main charge layer (4) increases   increasing the diameter of the coating (3) or the reinforcement from its narrow end (3 'to its base (3 ").   5. Device according to any one of the claims   tions, characterized by the fact that the distance between the different zones (19-23) for introducing the wave   detonation and the thickness of the main charge layer   (4) are mutually tuned so that the partial detonation waves transmitted by the different zones (19-23) are superimposed in the main charge to form a rectilinear ion wavefront at its   impact on the coating (3) or the frame.   6. Device according to claim 5, characterized in that the shortest path between the zone (19-23) each time considered introduction of the detonation wave and the coating (3) or the frame, is at least he   three times greater than the thickness of the connecting   (14-18) of the initial charge at the zone level   (19-23) introduction of the detonation wave.   7. Device according to any one of the claims   characterized in that the thickness of the different connecting branches (14-18) of the load initial is at least 1 mm.   8. Device according to any one of the claims   characterized in that the sections (6-10) of inert material are made of plastics material   and have a thickness of at least 10 mm.   9. Device according to any one of the claims   tions, characterized by the fact that the coating   (3) or the frame is made in the form of a pot.   10. Device according to any one of the claims   tions, characterized in that the ratio of the length of the explosive charge to its diameter is less than 2: 1.